Intraocular shunt implantation methods and devices

ABSTRACT

Devices and methods of implanting an intraocular shunt into an eye can be used to deliver the shunt to a location within the sclera. Some methods involve creating an opening in the sclera, and positioning a shunt in the anterior chamber of the eye such that the shunt terminates via the opening in the intrascleral space, thereby facilitating fluid flow through both the opening and the intrascleral space.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application a continuation of U.S. patent application Ser. No. 13/778,873, filed on Feb. 27, 2013, the entirety of which is incorporated herein by reference.

FIELD

The present disclosure generally relates to devices and methods of implanting an intraocular shunt into an eye.

BACKGROUND

Glaucoma is a disease in which the optic nerve is damaged, leading to progressive, irreversible loss of vision. It is typically associated with increased pressure of the fluid (i.e., aqueous humor) in the eye. Untreated glaucoma leads to permanent damage of the optic nerve and resultant visual field loss, which can progress to blindness. Once lost, this damaged visual field cannot be recovered. Glaucoma is the second leading cause of blindness in the world, affecting 1 in 200 people under the age of fifty, and 1 in 10 over the age of eighty for a total of approximately 70 million people worldwide.

The importance of lowering intraocular pressure (TOP) in delaying glaucomatous progression has been well documented. When drug therapy fails, or is not tolerated, surgical intervention is warranted. Surgical filtration methods for lowering intraocular pressure by creating a fluid flow path between the anterior chamber and an area of lower pressure have been described. Intraocular shunts can be positioned in the eye to drain fluid from the anterior chamber to locations such as the sub-Tenon's space, the subconjunctival space, the episcleral vein, the suprachoroidal space, Schlemm's canal, and the intrascleral space.

Positioning of an intraocular shunt to drain fluid into the intrascleral space is promising because it avoids contact with the conjunctiva and the suprachoroidal space. Avoiding contact with the conjunctiva and choroid is important because it reduces irritation, inflammation and tissue reaction, that can lead to fibrosis and reduce the outflow potential of the subconjunctival and suprachoroidal space. The conjunctiva itself plays a critical role in glaucoma filtration surgery. A less irritated and healthy conjunctiva allows drainage channels to form and less opportunity for inflammation and scar tissue formation. intrascleral shunt placement safeguards the integrity of the conjunctiva and choroid, but may provide only limited outflow pathways that may affect the long term TOP lowering efficacy.

SUMMARY

The present disclosure combines intrascleral shunt placement with creation of a passageway through the sclera, thereby facilitating fluid drainage from the intrascleral space. Such a passageway facilitates drainage of fluid into the subconjunctival and suprachoroidal spaces. The disclosure combines the advantages of intrascleral shunt placement, while utilizing an additional drainage passageway that prevents the natural drainage structures in the intrascleral space from becoming overwhelmed with fluid from the shunt.

In certain aspects, methods disclosed herein involve creating an opening in the sclera and positioning a shunt in the anterior chamber of the eye such that the shunt terminates via the opening in the intrascleral space, thereby facilitating fluid flow through both the opening and the intrascleral space. The outlet of the shunt may be positioned in various places within the intrascleral space. For example, the outlet may be positioned within the intrascleral space and may be positioned such that the outlet is even with the opening through the sclera.

Various different implantation methods exist and all are compatible with methods disclosed herein. In certain embodiments, an ab interno transpupil approach is employed to implant the shunt. Such a method general involves advancing a shaft configured to hold an intraocular shunt across an anterior chamber of an eye, creating first and second openings in either end of the sclera, and then retracting the shaft to within the intrascleral space. A shunt is then deployed to form a passage from the anterior chamber of the eye to the intrascleral space, such that the outlet of the shunt is positioned so that at least some of the fluid that exits the shunt flows through the second opening in the sclera. The first opening in the sclera may be made in any manner. In certain embodiments, the shaft creates the first opening in the sclera. In other embodiments, a tool other than the shaft creates the first opening in the sclera. The shaft is typically withdrawn from the sclera.

Alternatively, an ab externo implantation method (avoiding a transpupil approach) may be used. The final placement of the shunt and the flow characteristics of the ab externo method are identical to those in the ab interno method. The difference is the way in which the shunt is introduced into the intrascleral space. As opposed to the ab interno method described above, where the first opening in the sclera is performed approaching from the anterior chamber, the ab externo method involves creating the first opening in the sclera from the outside, coming through the conjunctival tissue layer. By penetrating all the way through the sclera and the tissue layers of the anterior angle of the eye, a second opening is created in the sclera that provides access to the anterior chamber. The shunt is implanted through the second opening such that the shunt forms a passage from the anterior chamber of the eye to the intrascleral space of the eye, so that the outlet of the shunt is positioned proximate to the second opening in the sclera. In that way at least some fluid that exits the shunt through the first opening in the sclera into the subconjunctival space. In certain embodiments, a shaft that holds the intraocular shunt creates the opening in the sclera. In some embodiments the scleral tunnel is extended to become a longer s-shaped tunnel that exits/enters further away from the limbus.

In certain circumstances, is it advantages to create a long scleral channel in order to increase fluid absorption within the sclera as well as to shift the subconjunctival drainage exit further down (posterior) from the limbus to a location of lower fibrotic tissue response. To achieve this for the ab interno approach, the scleral tunnel is extended in length by applying a downward pressure of the shaft after the shaft has entered the sclera. This downward pressure creates a deformation of the scleral tissue and results in an extended scleral tunnel length. Applying this ab interno method with the downward pressure during the scleral penetration creates a scleral tunnel that is not only longer and exits further down from the limbus on the second scleral opening but also results in an “S-shaped” scleral tunnel versus a shorter, straighter line. This S-shaped tunnel provides the additional advantage of creating additional friction between a compliant, soft shunt and the scleral tunnel and therefore reducing the chance for shunt migration within the scleral tunnel.

To achieve the longer scleral tunnel for the ab externo approach, the shaft is first positioned further down (posterior) from the limbus and then after the shaft has entered the sclera an upward pressure is applied during the penetration of the sclera from the outside exit to the inside exit. This upward pressure creates a similar deformation of the scleral tissue and results in an extended scleral tunnel length. The internal (second) sclera exit is still positioned to fall within the anterior angle of the eye. Applying this ab externo method with the upward pressure during the scleral penetration creates a scleral tunnel, that is not only longer and starts further down from the limbus on the second scleral opening but also results is a S-shaped scleral tunnel versus a shorter, straighter line. This S-shaped tunnel provides the additional advantage of creating additional friction between a compliant, soft shunt and the scleral tunnel and therefore reducing the chance for shunt migration within the scleral tunnel.

In other embodiments, a tool other than a shaft that holds the intraocular shunt creates the opening in the sclera.

The deployment device may be any device that is suitable for implanting an intraocular shunt into an eye. Such devices generally include a shaft connected to a deployment mechanism. In some devices, a shunt is positioned over an exterior of the shaft and the deployment mechanism works to deploy the shunt from an exterior of the shaft. In other devices, the shaft is hollow and the shunt is at least partially disposed in the shaft. In those devices, the deployment mechanism works to deploy the shunt from within the shaft. Depending on the device, a distal portion of the shaft may be sharpened or blunt, or straight, or curved.

Intraocular shunts used with methods disclosed herein define a hollow body that is configured to form a passage from the anterior chamber of the eye to the intrascleral space. In particular, the hollow body has a length sufficient to provide a passageway between the anterior chamber and the intrascleral space.

In certain aspects, the disclosure generally provides shunts composed of a material that has an elasticity modulus that is compatible with an elasticity modulus of tissue surrounding the shunt. In this manner, shunts disclosed herein are flexibility-matched with the surrounding tissue, and thus will remain in place after implantation without the need for any type of anchor that interacts with the surrounding tissue. Consequently, shunts disclosed herein will maintain fluid flow away for an anterior chamber of the eye after implantation without causing irritation or inflammation to the tissue surrounding the eye.

In other aspects, the disclosure generally provides shunts in which a portion of the shunt is composed of a flexible material that is reactive to pressure, i.e., an inner diameter of the shunt fluctuates depending upon the pressures exerted on that portion of the shunt. Thus, the flexible portion of the shunt acts as a valve that regulates fluid flow through the shunt. After implantation, intraocular shunts have pressure exerted upon them by tissues surrounding the shunt (e.g., scleral tissue) and pressure exerted upon them by aqueous humor flowing through the shunt. When the pressure exerted on the flexible portion of the shunt by the surrounding tissue is greater than the pressure exerted on the flexible portion of the shunt by the fluid flowing through the shunt, the flexible portion decreases in diameter, restricting flow through the shunt. The restricted flow results in aqueous humor leaving the anterior chamber at a reduced rate.

When the pressure exerted on the flexible portion of the shunt by the fluid flowing through the shunt is greater than the pressure exerted on the flexible portion of the shunt by the surrounding tissue, the flexible portion increases in diameter, increasing flow through the shunt. The increased flow results in aqueous humor leaving the anterior chamber at an increased rate.

The flexible portion of the shunt may be any portion of the shunt. In certain embodiments, the flexible portion is a distal portion of the shunt. In certain embodiments, the entire shunt is composed of the flexible material.

Other aspects of the disclosure generally provide multi-port shunts. Such shunts reduce probability of the shunt clogging after implantation because fluid can enter or exit the shunt even if one or more ports of the shunt become clogged with particulate. In certain embodiments, the shunt includes a hollow body defining a flow path and more than two ports, in which the body is configured such that a proximal portion receives fluid from the anterior chamber of an eye and a distal portion directs the fluid to a location of lower pressure with respect to the anterior chamber.

The shunt may have many different configurations. In certain embodiments, the proximal portion of the shunt (i.e., the portion disposed within the anterior chamber of the eye) includes more than one port and the distal portion of the shunt (i.e., the portion that is located in the intrascleral space) includes a single port. In other embodiments, the proximal portion includes a single port and the distal portion includes more than one port. In still other embodiments, the proximal and the distal portions include more than one port.

The ports may be positioned in various different orientations and along various different portions of the shunt. In certain embodiments, at least one of the ports is oriented at an angle to the length of the body. In certain embodiments, at least one of the ports is oriented 90.degree. to the length of the body.

The ports may have the same or different inner diameters. In certain embodiments, at least one of the ports has an inner diameter that is different from the inner diameters of the other ports.

Other aspects of the disclosure generally provide shunts with overflow ports. Those shunts are configured such that the overflow port remains closed until there is a pressure build-up within the shunt sufficient to force open the overflow port. Such pressure build-up typically results from particulate partially or fully clogging an entry or an exit port of the shunt. Such shunts reduce probability of the shunt clogging after implantation because fluid can enter or exit the shunt by the overflow port even if one port of the shunt becomes clogged with particulate.

In certain embodiments, the shunt includes a hollow body defining an inlet configured to receive fluid from an anterior chamber of the eye and an outlet configured to direct the fluid to a location of lower pressure with respect to the anterior chamber, the body further including at least one slit. The slit may be located at any place along the body of the shunt. In certain embodiments, the slit is located in proximity to the inlet. In other embodiments, the slit is located in proximity to the outlet. In certain embodiments, there is a slit in proximity to both the inlet and the outlet of the shunt.

In certain embodiments, the slit has a width that is substantially the same or less than an inner diameter of the inlet. In other embodiments, the slit has a width that is substantially the same or less than an inner diameter of the outlet. Generally, the slit does not direct the fluid unless the outlet is obstructed. However, the shunt may be configured such that the slit does direct at least some of the fluid even if the inlet or outlet is not obstructed.

In other aspects, the disclosure generally provides a shunt having a variable inner diameter. In particular embodiments, the diameter increases from inlet to outlet of the shunt. By having a variable inner diameter that increases from inlet to outlet, a pressure gradient is produced and particulate that may otherwise clog the inlet of the shunt is forced through the inlet due to the pressure gradient. Further, the particulate will flow out of the shunt because the diameter only increases after the inlet.

In certain embodiments, the shunt includes a hollow body defining a flow path and having an inlet configured to receive fluid from an anterior chamber of an eye and an outlet configured to direct the fluid to the intrascleral space, in which the body further includes a variable inner diameter that increases along the length of the body from the inlet to the outlet. In certain embodiments, the inner diameter continuously increases along the length of the body. In other embodiments, the inner diameter remains constant along portions of the length of the body. The shunts discussed above and herein are described relative to the eye and, more particularly, in the context of treating glaucoma and solving the above identified problems relating to intraocular shunts. Nonetheless, it will be appreciated that shunts described herein may find application in any treatment of a body organ requiring drainage of a fluid from the organ and are not limited to the eye.

In other aspects, the disclosure generally provides shunts for facilitating conduction of fluid flow away from an organ, the shunt including a body, in which at least one end of the shunt is shaped to have a plurality of prongs. Such shunts reduce probability of the shunt clogging after implantation because fluid can enter or exit the shunt by any space between the prongs even if one portion of the shunt becomes clogged with particulate.

The shunt may have many different configurations. In certain embodiments, the proximal end of the shunt (i.e., the portion disposed within the anterior chamber of the eye) is shaped to have the plurality of prongs. In other embodiments, the distal end of the shunt (i.e., the portion that is located in an area of lower pressure with respect to the anterior chamber such as the intrascleral space) is shaped to have the plurality of prongs. In other embodiments, both a proximal end and a distal end of the shunt are shaped to have the plurality of prongs. In particular embodiments, the shunt is a soft gel shunt.

In other aspects, the disclosure generally provides a shunt for draining fluid from an anterior chamber of an eye that includes a hollow body defining an inlet configured to receive fluid from an anterior chamber of the eye and an outlet configured to direct the fluid to a location of lower pressure with respect to the anterior chamber; the shunt being configured such that at least one end of the shunt includes a longitudinal slit. Such shunts reduce probability of the shunt clogging after implantation because the end(s) of the shunt can more easily pass particulate which would generally clog a shunt lacking the slits.

The shunt may have many different configurations. In certain embodiments, the proximal end of the shunt (i.e., the portion disposed within the anterior chamber of the eye) includes a longitudinal slit. In other embodiments, the distal end of the shunt (i.e., the portion that is located in an area of lower pressure with respect to the anterior chamber such as intrascleral space) includes a longitudinal slit. In other embodiments, both a proximal end and a distal end of the shunt include a longitudinal slit. In particular embodiments, the shunt is a soft gel shunt.

In certain embodiments, shunts disclosed herein may be coated or impregnated with at least one pharmaceutical and/or biological agent or a combination thereof. The pharmaceutical and/or biological agent may coat or impregnate an entire exterior of the shunt, an entire interior of the shunt, or both. Alternatively, the pharmaceutical and/or biological agent may coat and/or impregnate a portion of an exterior of the shunt, a portion of an interior of the shunt, or both. Methods of coating and/or impregnating an intraocular shunt with a pharmaceutical and/or biological agent are known in the art. See for example, Darouiche (U.S. Pat. Nos. 7,790,183; 6,719,991; 6,558,686; 6,162,487; 5,902,283; 5,853,745; and 5,624,704) and Yu et al. (U.S. patent application serial number 2008/0108933). The content of each of these references is incorporated by reference herein its entirety.

In certain embodiments, the exterior portion of the shunt that resides in the anterior chamber after implantation (e.g., about 1 mm of the proximal end of the shunt) is coated and/or impregnated with the pharmaceutical or biological agent. In other embodiments, the exterior of the shunt that resides in the scleral tissue after implantation of the shunt is coated and/or impregnated with the pharmaceutical or biological agent. In other embodiments, the exterior portion of the shunt that resides in the area of lower pressure (e.g., the intrascleral space) after implantation is coated and/or impregnated with the pharmaceutical or biological agent. In embodiments in which the pharmaceutical or biological agent coats and/or impregnates the interior of the shunt, the agent may be flushed through the shunt and into the area of lower pressure (e.g., the intrascleral space).

Any pharmaceutical and/or biological agent or combination thereof may be used with shunts disclosed herein. The pharmaceutical and/or biological agent may be released over a short period of time (e.g., seconds) or may be released over longer periods of time (e.g., days, weeks, months, or even years). Exemplary agents include anti-mitotic pharmaceuticals such as Mitomycin-C or 5-Fluorouracil, anti-VEGF (such as Lucentis, Macugen, Avastin, VEGF or steroids).

Other aspects of the disclosure provide a system for implanting an intraocular shunt into an eye that includes a shaft and an intraocular shunt, in which the shaft is configured to hold the intraocular shunt, the shunt is configured to be deployed from the shaft such that the shunt forms a passage from the anterior chamber of the eye to the intrascleral space of the eye and an outlet of the shunt is deployed proximate an opening through the sclera that has been made by a surgical instrument such that at least some fluid that exits the shunt flows through the opening in the sclera, and the shaft is configured to be withdrawn from the eye after the shunt is deployed.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 provides a cross-sectional diagram of the general anatomy of the eye.

FIG. 2 depicts, implantation of an intraocular shunt with a distal end of a deployment device holding a shunt, shown in cross section.

FIG. 3, panels A-H depict a sequence for ab interno shunt placement. FIG. 3, panel I depicts an implanted shunt in an S-shaped scleral passageway.

FIG. 4 depicts an example of a hollow shaft configured to hold an intraocular shunt fully within the shaft.

FIG. 5 depicts an intraocular shunt at least partially disposed within a hollow shaft of a deployment device.

FIG. 6 provides a schematic of a shunt having a flexible portion.

FIGS. 7A-7C provide schematics of a shunt implanted into an eye for regulation of fluid flow from the anterior chamber of the eye to a drainage structure of the eye.

FIGS. 8A-8C show different embodiments of multi-port shunts. FIG. 8A shows an embodiment of a shunt in which the proximal portion of the shunt includes more than one port and the distal portion of the shunt includes a single port. FIG. 8B shows another embodiment of a shunt in which the proximal portion includes a single port and the distal portion includes more than one port. FIG. 8C shows another embodiment of a shunt in which the proximal portions include more than one port and the distal portions include more than one port.

FIGS. 9A and 9B show different embodiments of multi-port shunts having different diameter ports.

FIGS. 10A-10C provide schematics of shunts having a slit located along a portion of the length of the shunt.

FIG. 11 depicts a shunt having multiple slits along a length of the shunt.

FIG. 12 depicts a shunt having a slit at a proximal end of the shunt.

FIG. 13 provides a schematic of a shunt that has a variable inner diameter.

FIGS. 14A-14D depict a shunt having multiple prongs at a distal and/or proximal end.

FIGS. 15A-15D depict a shunt having a longitudinal slit at a distal and/or proximal end.

FIG. 16 is a schematic showing an embodiment of a shunt deployment device according to the disclosure.

FIG. 17 shows an exploded view of the device shown in FIG. 16.

FIGS. 18A-19D are schematics showing different enlarged views of the deployment mechanism of the deployment device.

FIGS. 19A-19C are schematics showing interaction of the deployment mechanism with a portion of the housing of the deployment device.

FIG. 20 shows a cross sectional view of the deployment mechanism of the deployment device.

FIGS. 21A-21B show schematics of the deployment mechanism in a pre-deployment configuration. FIG. 21C shows an enlarged view of the distal portion of the deployment device of FIG. 21A. This figure shows an intraocular shunt loaded within a hollow shaft of the deployment device.

FIGS. 22A and 22B show schematics of the deployment mechanism at the end of the first stage of deployment of the shunt from the deployment device. FIG. 22C shows an enlarged view of the distal portion of the deployment device of FIG. 22A. This figure shows an intraocular shunt partially deployed from within a hollow shaft of the deployment device.

FIG. 23A shows a schematic of the deployment device after deployment of the shunt from the device. FIG. 23B show a schematic of the deployment mechanism at the end of the second stage of deployment of the shunt from the deployment device. FIG. 23C shows an enlarged view of the distal portion of the deployment device after retraction of the shaft with the pusher abutting the shunt. FIG. 23D shows an enlarged view of the distal portion of the deployment device after deployment of the shunt.

FIG. 24, panels A-G depict a sequence for ab externo shunt placement.

FIG. 25, panels A-B depict a sequence for ab externo insertion of a shaft of a deployment device using an applicator.

FIG. 26 depicts deployment of the shunt in the intra scleral space where a distal end of the shunt is flush with the sclera surface.

FIG. 27 depicts deployment of the shunt in the intra scleral space where a distal end of the shunt is about 200-500 μm behind the scleral exit.

FIG. 28 depicts deployment of the shunt in the intra scleral space where a distal end of the shunt is approximately more than 500 μm behind the scleral exit.

DETAILED DESCRIPTION

FIG. 1 provides a schematic diagram of the general anatomy of the eye. An anterior aspect of the anterior chamber 1 of the eye is the cornea 2, and a posterior aspect of the anterior chamber 1 of the eye is the iris 4. Beneath the iris 4 is the lens 5. The anterior chamber 1 is filled with aqueous humor 3. The aqueous humor 3 drains into a space(s) 6 below the conjunctiva 7 through the trabecular meshwork (not shown in detail) of the sclera 8. The aqueous humor is drained from the space(s) 6 below the conjunctiva 7 through a venous drainage system (not shown).

In conditions of glaucoma, the pressure of the aqueous humor in the eye (anterior chamber) increases and this resultant increase of pressure can cause damage to the vascular system at the back of the eye and especially to the optic nerve. The treatment of glaucoma and other diseases that lead to elevated pressure in the anterior chamber involves relieving pressure within the anterior chamber to a normal level.

Glaucoma filtration surgery is a surgical procedure typically used to treat glaucoma. The procedure involves placing a shunt in the eye to relieve intraocular pressure by creating a pathway for draining aqueous humor from the anterior chamber of the eye. The shunt is typically positioned in the eye such that it creates a drainage pathway between the anterior chamber of the eye and a region of lower pressure. Various structures and/or regions of the eye having lower pressure that have been targeted for aqueous humor drainage include Schlemm's canal, the subconjunctival space, the episcleral vein, the suprachoroidal space, or the subarachnoid space. Methods of implanting intraocular shunts are known in the art. Shunts may be implanted using an ab externo approach (entering through the conjunctiva and inwards through the sclera) or an ab interno approach (entering through the cornea, across the anterior chamber, through the trabecular meshwork and sclera).

Ab interno approaches for implanting an intraocular shunt in the subconjunctival space are shown for example in Yu et al. (U.S. Pat. No. 6,544,249 and U.S. patent publication number 2008/0108933) and Prywes (U.S. Pat. No. 6,007,511), the contents of each of which are incorporated by reference herein in its entirety. Briefly and with reference to FIG. 2, a surgical intervention to implant the shunt involves inserting into the eye a deployment device 15 that holds an intraocular shunt, and deploying the shunt within the eye 16. A deployment device 15 holding the shunt enters the eye 16 through the cornea 17 (ab interno approach). The deployment device 15 is advanced across the anterior chamber 20 (as depicted by the broken line) in what is referred to as a transpupil implant insertion. The deployment device 15 is advanced through the sclera 21 until a distal portion of the device is in proximity to the subconjunctival space. The shunt is then deployed from the deployment device, producing a conduit between the anterior chamber and the subconjunctival space to allow aqueous humor to drain through the conjunctival lymphatic system.

While such ab interno subconjunctival filtration procedures have been successful in relieving intraocular pressure, there is a substantial risk that the intraocular shunt may be deployed too close to the conjunctiva, resulting in irritation and subsequent inflammation and/or scarring of the conjunctiva, which can cause the glaucoma filtration procedure to fail (See Yu et al., Progress in Retinal and Eye Research, 28:303-328 (2009)). Additionally, commercially available shunts that are currently utilized in such procedures are not ideal for ab interno subconjunctival placement due to the length of the shunt (i.e., too long) and/or the materials used to make the shunt (e.g., gold, polymer, titanium, or stainless steel), and can cause significant irritation to the tissue surrounding the shunt, as well as the conjunctiva, if deployed too close.

The present disclosure provides methods for implanting intraocular shunts within the sclera (i.e., intrascleral implantation) and are thus suitable for use in an glaucoma filtration procedure (ab interno or ab externo). In methods disclosed herein, the implanted shunt forms a passage from the anterior chamber of the eye into the sclera (i.e., intrascleral space). Design and/or deployment of an intraocular shunt such that the inlet terminates in the anterior chamber and the outlet terminates intrascleral safeguards the integrity of the conjunctiva to allow subconjunctival drainage pathways to successfully form. Additionally, drainage into the intrascleral space provides access to more lymphatic channels than just the conjunctival lymphatic system, such as the episcleral lymphatic network.

Additionally, methods disclosed herein recognize that while intrascleral shunt placement avoids contact with the conjunctiva, fluid outflow from the shunt into the intrascleral space may overwhelm the natural drainage structures (e.g., the episcleral vessel complex) proximate the intrascleral space. The present disclosure combines intrascleral shunt placement with creation of a passageway through the sclera, thereby facilitating fluid drainage from the intrascleral space. Such a passageway facilitates diffusion of fluid into the subconjunctival and suprachoroidal spaces. Accordingly, the advantages of intrascleral shunt placement are recognized and the additional drainage passageway prevents the natural drainage structures proximate the intrascleral space from becoming overwhelmed with fluid output from the shunt.

Methods for Intrascleral Shunt Placement

The methods disclosed herein involve methods disclosed herein involve creating an opening in the sclera, and positioning a shunt in the anterior chamber of the eye such that the shunt terminates via the opening in the intrascleral space, thereby facilitating fluid flow through both the opening and the intrascleral space. The outlet of the shunt may be positioned in different places within the intrascleral space. For example, the outlet of the shunt may be positioned within the intrascleral space. Alternatively, the outlet of the shunt may be positioned such that the outlet is even with the opening through the sclera.

Methods of implanting intraocular shunts are known in the art. Shunts may be implanted using an ab externo approach (entering through the conjunctiva and inwards through the sclera) or an ab interno approach (entering through the cornea, across the anterior chamber, through the trabecular meshwork and sclera). The deployment device may be any device that is suitable for implanting an intraocular shunt into an eye. Such devices generally include a shaft connected to a deployment mechanism. In some devices, a shunt is positioned over an exterior of the shaft and the deployment mechanism works to deploy the shunt from an exterior of the shaft. In other devices, the shaft is hollow and the shunt is at least partially disposed in the shaft. In those devices, the deployment mechanism works to deploy the shunt from within the shaft. Depending on the device, a distal portion of the shaft may be sharpened or blunt, or straight or curved.

Ab interno approaches for implanting an intraocular shunt in the subconjunctival space are shown for example in Yu et al. (U.S. Pat. No. 6,544,249 and U.S. patent publication number 2008/0108933) and Prywes (U.S. Pat. No. 6,007,511), the contents of each of which are incorporated by reference herein in its entirety. An exemplary ab interno method employs a transpupil approach and involves creating a first opening in the sclera of an eye, advancing a shaft configured to hold an intraocular shunt across an anterior chamber of an eye and through the sclera to create a second opening in the sclera, retracting the shaft through the second opening to within the sclera (i.e., the intrascleral space), deploying the shunt from the shaft such that the shunt forms a passage from the anterior chamber of the eye to the intrascleral space of the eye, such that an outlet of the shunt is positioned so that at least some of the fluid that exits the shunt flows through the second opening in the sclera, and withdrawing the shaft from the eye. The first opening in the sclera may be made in any manner. In certain embodiments, the shaft creates the first opening in the sclera. In other embodiments, a tool other than the shaft creates the first opening in the sclera.

In certain embodiments, the methods disclosed herein generally involve inserting into the eye a hollow shaft configured to hold an intraocular shunt. In certain embodiments, the hollow shaft is a component of a deployment device that may deploy the intraocular shunt. The shunt is then deployed from the shaft into the eye such that the shunt forms a passage from the anterior chamber into the sclera (i.e., the intrascleral space). The hollow shaft is then withdrawn from the eye.

To place the shunt within the eye, a surgical intervention to implant the shunt is performed that involves inserting into the eye a deployment device that holds an intraocular shunt, and deploying at least a portion of the shunt within intrascleral space. FIG. 3, panels A-H provides an exemplary sequence for ab interno shunt placement. In certain embodiments, a hollow shaft 9 of a deployment device holding the shunt 12 enters the eye through the cornea (ab interno approach, FIG. 3, panel A). The shaft 9 is advanced across the anterior chamber 10 in what is referred to as a transpupil implant insertion. The shaft 9 is advanced through the anterior angle tissues of the eye and into the sclera 8 and further advanced until it passes through the sclera 8, thereby forming a second opening in the sclera 8 (FIG. 3, panels B-C). Once the second opening in the sclera 8 is achieved, the shaft 9 is retracted all the way back through the sclera 8 and into the anterior chamber of the eye 10 (FIG. 3, panels D-G). During this shaft retraction, the shunt 12 is held in place by a plunger rod 11 that is positioned behind the proximal end of the shunt 12. After the shaft 9 has been completely withdrawn from the sclera 8, the plunger rod 11 is withdrawn as well and the shunt implantation sequence is complete (FIG. 3, panel H). This process results in an implanted shunt 12 in which a distal end of the shunt 12 is proximate a passageway 14 through the sclera 8. Once fully deployed, a proximal end of shunt 12 resides in the anterior chamber 10 and a distal end of shunt 12 resides in the intrascleral space. Preferably a sleeve 13 is used around the shaft 12 and designed in length such that the sleeve 13 acts as a stopper for the scleral penetration of the shaft and also determines the longitudinal placement of the proximal end of the shunt.

Insertion of the shaft of the deployment device into the sclera 8 produces a long scleral channel of about 2 mm to about 5 mm in length. Withdrawal of the shaft of the deployment device prior to deployment of the shunt 12 from the device produces a space in which the shunt 12 may be deployed. Deployment of the shunt 12 allows for aqueous humor 3 to drain into traditional fluid drainage channels of the eye (e.g., the intrascleral vein, the collector channel, Schlemm's canal, the trabecular outflow, and the uveoscleral outflow to the ciliary muscle. The deployment is performed such that an outlet of the shunt is positioned proximate the opening in the sclera so that at least some of the fluid that exits the shunt flows through the opening in the sclera, thereby ensuring that the intrascleral space does not become overwhelmed with fluid output from the shunt.

FIG. 4 provides an exemplary schematic of a hollow shaft for use in accordance with the methods disclosed herein. This figure shows a hollow shaft 22 that is configured to hold an intraocular shunt 23. The shaft may hold the shunt within the hollow interior 24 of the shaft, as is shown in FIG. 4. Alternatively, the hollow shaft 22 may hold the shunt on an outer surface 25 of the shaft. In particular embodiments, the shunt is held completely within the hollow interior 24 of the shaft 22, as is shown in FIG. 4. In other embodiments, the shunt is only partially disposed within the hollow shaft 22, as shown in FIG. 5. Generally, in one embodiment, the intraocular shunts are of a cylindrical shape and have an outside cylindrical wall and a hollow interior. The shunt may have an inside diameter of approximately 10-250 μm, an outside diameter of approximately 100-450 μm, and a length of approximately 1-12 mm. In particular embodiments, the shunt has a length of approximately 2-10 mm and an outside diameter of approximately 150-400 μm. The hollow shaft 22 is configured to at least hold a shunt of such shape and such dimensions. However, the hollow shaft 22 may be configured to hold shunts of different shapes and different dimensions than those described above, and the disclosure encompasses a shaft 22 that may be configured to hold any shaped or dimensioned intraocular shunt.

Preferably, the methods disclosed herein are conducted by making an incision in the eye prior to insertion of the deployment device. Although in particular embodiments, the methods disclosed herein may be conducted without making an incision in the eye prior to insertion of the deployment device. In certain embodiments, the shaft that is connected to the deployment device has a sharpened point or tip. In certain embodiments, the hollow shaft is a needle. Exemplary needles that may be used are commercially available from Terumo Medical Corp. (Elkington Md.). In a particular embodiment, the needle has a hollow interior and a beveled tip, and the intraocular shunt is held within the hollow interior of the needle. In another particular embodiment, the needle has a hollow interior and a triple ground point or tip.

The methods disclosed herein are preferably conducted without needing to remove an anatomical portion or feature of the eye, including but not limited to the trabecular meshwork, the iris, the cornea, or aqueous humor. The methods disclosed herein are also preferably conducted without inducing substantial ocular inflammation, such as subconjunctival blebbing or endophthalmitis. Such methods can be achieved using an ab interno approach by inserting the hollow shaft configured to hold the intraocular shunt through the cornea, across the anterior chamber, through the trabecular meshwork and into the sclera. However, the methods disclosed herein may be conducted using an ab externo approach.

When the methods disclosed herein are conducted using an ab interno approach, the angle of entry through the cornea as well as the up and downward forces applied to the shaft during the scleral penetration affect optimal placement of the shunt in the intrascleral space. Preferably, the hollow shaft is inserted into the eye at an angle above the corneal limbus, in contrast with entering through or below the corneal limbus. For example, the hollow shaft is inserted approximately 0.25 to 3.0 mm, preferably approximately 0.5 to 2.5 mm, more preferably approximately 1.0 mm to 2.0 mm above the corneal limbus, or any specific value within said ranges, e.g., approximately 1.0 mm, approximately 1.1 mm, approximately 1.2 mm, approximately 1.3 mm, approximately 1.4 mm, approximately 1.5 mm, approximately 1.6 mm, approximately 1.7 mm, approximately 1.8 mm, approximately 1.9 mm or approximately 2.0 mm above the corneal limbus.

Without intending to be bound by any theory, placement of the shunt farther from the limbus at the exit site, as provided by an angle of entry above the limbus, as well as an S-shaped scleral tunnel (FIG. 3, panel I) due to applied up or downward pressure during the scleral penetration of the shaft is believed to provide access to more lymphatic channels for drainage of aqueous humor, such as the episcleral lymphatic network, in addition to the conjunctival lymphatic system.

In other embodiments, an ab externo approach is employed. Ab externo implantation approaches are shown for example in Nissan et al. (U.S. Pat. No. 8,109,896), Tu et al. (U.S. Pat. No. 8,075,511), and Haffner et al. (U.S. Pat. No. 7,879,001), the content of each of which is incorporated by reference herein in its entirety. An exemplary ab externo approach avoids having to make a scleral flap. In this preferred embodiment, a distal end of the deployment device is used to make an opening into the eye and into the sclera. For example, a needle is inserted from ab externo through the sclera and exits the anterior angle of the eye. The needle is then withdrawn, leaving a scleral slit behind. A silicone tube with sufficient stiffness is then manually pushed through the scleral slit from the outside so that the distal tube ends distal to the Trabecular Meshwork in the anterior chamber of the eye. Towards the proximal end, the tube exits the sclera, lays on top of it, and connects on its proximal end to a plate that is fixated by sutures to the outside scleral surface far away (>10 mm) from the limbus.

FIG. 24 panels A-H describes another ab externo method that uses a deployment device. In this method, a distal portion of the deployment device includes a hollow shaft 9 that has a sharpened tip (FIG. 24, panel A). A shunt 12 resides within the shaft 9. The distal shaft 9 is advanced into the eye and into the sclera 8 until a proximal portion of the shaft resides in the anterior chamber 10 and a distal portion of the shaft 9 is inside the scleral 8 (FIG. 24, panels B-D). Deployment of the shunt 12 that is located inside the shaft 9 is then accomplished by a mechanism that withdraws the shaft 9 while the shunt 12 is held in place by a plunger 11 behind the proximal end of the shunt 12 (FIG. 24, panels E-H). As the implantation sequence progresses, the shaft 9 is completely withdrawn from the sclera 8. After that, the plunger 11 is withdrawn from the sclera 8, leaving the shunt 12 behind with its distal end inside the sclera 8, its proximal end inside the anterior chamber 10, and a passageway 14 through the sclera 8. In a preferred embodiment the shaft 9 is placed inside a sleeve 13 that is dimensioned in length relative to the shaft 9 such that it will act as stopper during the penetration of the shaft 9 into the eye and at the same time assures controlled longitudinal placement of the shunt 12 relative to the outer surface of the eye. The sleeve 13 may be beveled to match the anatomical angle of the entry site surface.

The shaft penetrates the conjunctival layer before it enters and penetrates the sclera. This causes a conjunctival hole, that could create a fluid leakage after the shunt placement has been completed. To minimize the chance for any leakage, a small diameter shaft is used that results in a self-sealing conjunctival wound. To further reduce the chance for a conjunctival leak, a suture can be placed in the conjunctiva around the penetration area after the shunt placement.

Furthermore the preferred method of penetrating the conjunctiva is performed by shifting the conjunctival layers from posterior to the limbus towards the limbus, using e.g. an applicator such as a Q-tip, before the shaft penetration is started. This is illustrates in FIG. 25, panels A-B. That figure shows that an applicator 57 is put onto the conjunctiva 58, approximately 6 mm away from the limbus. The loose conjunctiva layer is then pushed towards the limbus to create folding tissue layers that are 2 mm away from the limbus. The device shaft 9 is now inserted through the conjunctiva and sclera 8 starting 4 mm away from the limbus. After the shunt placement has been completed, the Q-tip is released and the conjunctival perforation relaxes back from 4 mm to around 8 mm limbal distance. That causes the conjunctival perforation to be 4 mm away from the now slowly starting drainage exit. This distance will reduce any potential for leakage and allows for a faster conjunctival healing response. Alternative to this described upward shift, a sideway shift of the conjunctiva or anything in between is feasible as well. In another embodiment of the ab externo method, a conjunctival slit is cut and the conjunctiva is pulled away from the shaft entry point into the sclera. After the shunt placement is completed, the conjunctival slit is closed again through sutures.

In certain embodiments, since the tissue surrounding the trabecular meshwork is optically opaque, an imaging technique, such as ultrasound biomicroscopy (UBM), optical coherence tomography (OCT) or a laser imaging technique, can be utilized. The imaging can provide guidance for the insertion of the deployment device and the deployment of the shunt. This technique can be used with a large variety of shunt embodiments with slight modifications since the trabecular meshwork is punctured from the scleral side, rather than the anterior chamber side, in the ab externo insertion.

In another ab externo approach, a superficial flap may be made in the sclera and then a second deep scleral flap may be created and excised leaving a scleral reservoir under the first flap. Alternatively, a single scleral flap may be made with or without excising any portion of the sclera.

A shaft of a deployment device is inserted under the flap and advanced through the sclera and into an anterior chamber. The shaft is advanced into the sclera until a proximal portion of the shaft resides in the anterior chamber and a distal portion of the shaft is in proximity to the trabecular outflow. The deployment is then performed such that an outlet of the shunt is positioned proximate the second opening in the sclera so that at least some of the fluid that exits the shunt flows through the first opening in the sclera, thereby ensuring that the intrascleral space does not become overwhelmed with fluid output from the shunt. At the conclusion of the ab externo implantation procedure, the scleral flap may be sutured closed. The procedure also may be performed without suturing.

Regardless of the implantation method employed, methods disclosed herein recognize that the proximity of the distal end of the shunt to the scleral exit slit affects the flow resistance through the shunt, and therefore affects the intraocular pressure in the eye. For example, if the distal end of the shunt 12 is flush with the sclera surface then there is no scleral channel resistance (FIG. 26). In this embodiment, total resistance comes from the shunt 12 alone. In another embodiment, if the distal end of the shunt 12 is about 200-500 μm behind the scleral exit, then the scleral slit closes partially around the exit location, adding some resistance to the outflow of aqueous humor (FIG. 27). In another embodiments, if the distal end of the shunt 12 is approximately more than 500 μm behind the scleral exit, than the scleral slit closes completely around the exit location with no backpressure and opens gradually to allow aqueous humor to seep out when the intraocular pressure raises e.g. above 10 mmHg (FIG. 28). The constant seepage of aqueous humor keeps the scleral slit from scaring closed over time.

Effectively, shunt placement according to methods disclosed herein achieves a valve like performance where the scleral slit in front of the distal shunt end acts like a valve. The opening (cracking) pressure of this valve can be adjusted by the outer shunt diameter and its exact distal end location relative to the scleral exit site. Typical ranges of adjustment are 1 mmHg to 20 mmHg. This passageway distance can be controlled and adjusted through the design of the inserting device as well as the shunt length and the deployment method. Therefore a specific design can be chosen to reduce or prevent hypotony (<6 mmHg) as a post-operative complication.

Intraocular Shunts

The present disclosure provides intraocular shunts that are configured to form a drainage pathway from the anterior chamber of the eye to the intrascleral space. In particular, the intraocular shunts disclosed herein have a length that is sufficient to form a drainage pathway from the anterior chamber of the eye to the intrascleral space. The length of the shunt is important for achieving placement specifically in the intrascleral space. A shunt that is too long will extend beyond the intrascleral space and irritate the conjunctiva which can cause the filtration procedure to fail, as previously described. A shunt that is too short will not provide sufficient access to drainage pathways such as the episcleral lymphatic system or the conjunctival lymphatic system.

Shunts disclosed herein may be any length that allows for drainage of aqueous humor from an anterior chamber of an eye to the intrascleral space. Exemplary shunts range in length from approximately 1 mm to approximately 10 mm or between approximately 2 mm to approximately 6 mm, or any specific value within said ranges. In certain embodiments, the length of the shunt is between approximately 2 to 4 mm, or any specific value within said range, The intraocular shunts disclosed herein are particularly suitable for use in an ab interno glaucoma filtration procedure. Commercially available shunts that are currently used in ab interno filtration procedures are typically made of a hard, inflexible material such as gold, polymer, titanium, or stainless steel, and cause substantial irritation of the eye tissue, resulting in ocular inflammation such as subconjunctival blebbing or endophthalmitis. The methods disclosed herein may be conducted using any commercially available shunts, such as the Optonol Ex-PRESS™ mini Glaucoma shunt, and the Solx DeepLight Gold™ Micro-Shunt.

In particular embodiments, the intraocular shunts disclosed herein are flexible, and have an elasticity modulus that is substantially identical to the elasticity modulus of the surrounding tissue in the implant site. As such, the intraocular shunts disclosed herein are easily bendable, do not erode or cause a tissue reaction, and do not migrate once implanted. Thus, when implanted in the eye using an ab interno procedure, such as the methods described herein, the intraocular shunts disclosed herein do not induce substantial ocular inflammation such as subconjunctival blebbing or endophthalmitis. Additional exemplary features of the intraocular shunts disclosed herein are discussed in further detail below.

Tissue Compatible Shunts

In certain aspects, the disclosure generally provides shunts composed of a material that has an elasticity modulus that is compatible with an elasticity modulus of tissue surrounding the shunt. In this manner, shunts disclosed herein are flexibility matched with the surrounding tissue, and thus will remain in place after implantation without the need for any type of anchor that interacts with the surrounding tissue. Consequently, shunts disclosed herein will maintain fluid flow away for an anterior chamber of the eye after implantation without causing irritation or inflammation to the tissue surrounding the eye.

Elastic modulus, or modulus of elasticity, is a mathematical description of an object or substance's tendency to be deformed elastically when a force is applied to it. The elastic modulus of an object is defined as the slope of its stress-strain curve in the elastic deformation region:

$\lambda\overset{def}{=}\frac{stress}{strain}$ where lambda (λ) is the elastic modulus; stress is the force causing the deformation divided by the area to which the force is applied; and strain is the ratio of the change caused by the stress to the original state of the object. The elasticity modulus may also be known as Young's modulus (E), which describes tensile elasticity, or the tendency of an object to deform along an axis when opposing forces are applied along that axis. Young's modulus is defined as the ratio of tensile stress to tensile strain. For further description regarding elasticity modulus and Young's modulus, see for example Gere (Mechanics of Materials, 6^(th) Edition, 2004, Thomson), the content of which is incorporated by reference herein in its entirety.

The elasticity modulus of any tissue can be determined by one of skill in the art. See for example Samani et al. (Phys. Med. Biol. 48:2183, 2003); Erkamp et al. (Measuring The Elastic Modulus Of Small Tissue Samples, Biomedical Engineering Department and Electrical Engineering and Computer Science Department University of Michigan Ann Arbor, Mich. 48109-2125; and Institute of Mathematical Problems in Biology Russian Academy of Sciences, Pushchino, Moscow Region 142292 Russia); Chen et al. (IEEE Trans. Ultrason. Ferroelec. Freq. Control 43:191-194, 1996); Hall, (In 1996 Ultrasonics Symposium Proc., pp. 1193-1196, IEEE Cat. No. 96CH35993, IEEE, New York, 1996); and Parker (Ultrasound Med. Biol. 16:241-246, 1990), each of which provides methods of determining the elasticity modulus of body tissues. The content of each of these is incorporated by reference herein in its entirety.

The elasticity modulus of tissues of different organs is known in the art. For example, Pierscionek et al. (Br J Ophthalmol, 91:801-803, 2007) and Friberg (Experimental Eye Research, 473:429-436, 1988) show the elasticity modulus of the cornea and the sclera of the eye. The content of each of these references is incorporated by reference herein in its entirety. Chen, Hall, and Parker show the elasticity modulus of different muscles and the liver. Erkamp shows the elasticity modulus of the kidney.

Shunts disclosed herein are composed of a material that is compatible with an elasticity modulus of tissue surrounding the shunt. In certain embodiments, the material has an elasticity modulus that is substantially identical to the elasticity modulus of the tissue surrounding the shunt. In other embodiments, the material has an elasticity modulus that is greater than the elasticity modulus of the tissue surrounding the shunt. Exemplary materials includes biocompatible polymers, such as polycarbonate, polyethylene, polyethylene terephthalate, polyimide, polystyrene, polypropylene, poly(styrene-b-isobutylene-b-styrene), or silicone rubber.

In particular embodiments, shunts disclosed herein are composed of a material that has an elasticity modulus that is compatible with the elasticity modulus of tissue in the eye, particularly scleral tissue. In certain embodiments, compatible materials are those materials that are softer than scleral tissue or marginally harder than scleral tissue, yet soft enough to prohibit shunt migration. The elasticity modulus for anterior scleral tissue is approximately 2.9+/1.4×10⁶ N/m², and 1.8+/−1.1×10⁶ N/m² for posterior scleral tissue. See Friberg (Experimental Eye Research, 473:429-436, 1988). An exemplary material is cross linked gelatin derived from Bovine or Porcine Collagen.

The disclosure encompasses shunts of different shapes and different dimensions, and the shunts disclosed herein may be any shape or any dimension that may be accommodated by the eye. In certain embodiments, the intraocular shunt is of a cylindrical shape and has an outside cylindrical wall and a hollow interior. The shunt may have an inside diameter from approximately 10 μm to approximately 250 μm, an outside diameter from approximately 100 μm to approximately 450 μm, and a length from approximately 2 mm to approximately 10 mm.

Shunts Reactive to Pressure

In other aspects, the disclosure generally provides shunts in which a portion of the shunt is composed of a flexible material that is reactive to pressure, i.e., the diameter of the flexible portion of the shunt fluctuates depending upon the pressures exerted on that portion of the shunt. FIG. 6 provides a schematic of a shunt 23 having a flexible portion 51. In this figure, the flexible portion 51 is shown in the middle of the shunt 23. However, the flexible portion 51 may be located in any portion of the shunt, such as the proximal or distal portion of the shunt. In certain embodiments, the entire shunt is composed of the flexible material, and thus the entire shunt is flexible and reactive to pressure.

The flexible portion 51 of the shunt 23 acts as a valve that regulates fluid flow through the shunt. The human eye produces aqueous humor at a rate of about 2 μl/min for approximately 3 ml/day. The entire aqueous volume is about 0.25 ml. When the pressure in the anterior chamber falls after surgery to about 7-8 mmHg, it is assumed the majority of the aqueous humor is exiting the eye through the implant since venous backpressure prevents any significant outflow through normal drainage structures (e.g., the trabecular meshwork).

After implantation, intraocular shunts have pressure exerted upon them by tissues surrounding the shunt (e.g., scleral tissue such as the sclera channel and the sclera exit) and pressure exerted upon them by aqueous humor flowing through the shunt. The flow through the shunt, and thus the pressure exerted by the fluid on the shunt, is calculated by the equation:

$\Phi = {\frac{dV}{dt} = {{{\upsilon\pi}\; R^{2}} = {{\frac{\pi\; R^{4}}{8\eta}\left( \frac{{- \Delta}\; P}{\Delta\; x} \right)} = {\frac{\pi\; R^{4}}{8\eta}\frac{{\Delta\; P}}{L}}}}}$ Where Φ is the volumetric flow rate; V is a volume of the liquid poured (cubic meters); t is the time (seconds); V is mean fluid velocity along the length of the tube (meters/second); x is a distance in direction of flow (meters); R is the internal radius of the tube (meters); ΔP is the pressure difference between the two ends (pascals); η is the dynamic fluid viscosity (pascal-second (Pas)); and L is the total length of the tube in the x direction (meters).

FIG. 7A provides a schematic of a shunt 26 implanted into an eye for regulation of fluid flow from the anterior chamber of the eye to an area of lower pressure (e.g., the intrascleral space). The shunt is implanted such that a proximal end 27 of the shunt 26 resides in the anterior chamber 28 of the eye, and a distal end 29 of the shunt 26 resides outside of the anterior chamber to conduct aqueous humor from the anterior chamber to an area of lower pressure. A flexible portion 30 of the shunt 26 spans at least a portion of the sclera of the eye. As shown in FIG. 7A, the flexible portion 30 spans an entire length of the sclera 31.

When the pressure exerted on the flexible portion 30 of the shunt 26 by sclera 31 (vertical arrows) is greater than the pressure exerted on the flexible portion 30 of the shunt 26 by the fluid flowing through the shunt (horizontal arrow), the flexible portion 30 decreases in diameter, restricting flow through the shunt 26 (FIG. 7B). The restricted flow results in aqueous humor leaving the anterior chamber 28 at a reduced rate.

When the pressure exerted on the flexible portion 30 of the shunt 26 by the fluid flowing through the shunt (horizontal arrow) is greater than the pressure exerted on the flexible portion 30 of the shunt 26 by the sclera 31 (vertical arrows), the flexible portion 30 increases in diameter, increasing flow through the shunt 26 (FIG. 7C). The increased flow results in aqueous humor leaving the anterior chamber 28 at an increased rate.

The disclosure encompasses shunts of different shapes and different dimensions, and the shunts disclosed herein may be any shape or any dimension that may be accommodated by the eye. In certain embodiments, the intraocular shunt is of a cylindrical shape and has an outside cylindrical wall and a hollow interior. The shunt may have an inside diameter from approximately 10 μm to approximately 250 μm, an outside diameter from approximately 100 μm to approximately 450 μm, and a length from approximately 2 mm to approximately 10 mm.

In a particular embodiments, the shunt has a length of about 6 mm and an inner diameter of about 64 μm. With these dimensions, the pressure difference between the proximal end of the shunt that resides in the anterior chamber and the distal end of the shunt that resides outside the anterior chamber is about 4.3 mmHg. Such dimensions thus allow the implant to act as a controlled valve and protect the integrity of the anterior chamber.

It will be appreciated that different dimensioned implants may be used. For example, shunts that range in length from about 2 mm to about 10 mm and have a range in inner diameter from about 10 μm to about 100 μm allow for pressure control from approximately 0.5 mmHg to approximately 20 mmHg.

The material of the flexible portion and the thickness of the wall of the flexible portion will determine how reactive the flexible portion is to the pressures exerted upon it by the surrounding tissue and the fluid flowing through the shunt. Generally, with a certain material, the thicker the flexible portion, the less responsive the portion will be to pressure. In certain embodiments, the flexible portion is a gelatin or other similar material, and the thickness of the gelatin material forming the wall of the flexible portion ranges from about 10 μm thick to about 100 μm thick.

In a certain embodiment, the gelatin used for making the flexible portion is known as gelatin Type B from bovine skin. An exemplary gelatin is PB Leiner gelatin from bovine skin, Type B, 225 Bloom, USP. Another material that may be used in the making of the flexible portion is a gelatin Type A from porcine skin, also available from Sigma Chemical. Such gelatin is available from Sigma Chemical Company of St. Louis, Mo. under Code G-9382. Still other suitable gelatins include bovine bone gelatin, porcine bone gelatin and human-derived gelatins. In addition to gelatins, the flexible portion may be made of hydroxypropyl methylcellulose (HPMC), collagen, polylactic acid, polyglycolic acid, hyaluronic acid and glycosaminoglycans. In certain embodiments, the gelatin is cross-linked. Cross-linking increases the inter- and intramolecular binding of the gelatin substrate. Any method for cross-linking the gelatin may be used. In a particular embodiment, the formed gelatin is treated with a solution of a cross-linking agent such as, but not limited to, glutaraldehyde. Other suitable compounds for cross-linking include 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide (EDC). Cross-linking by radiation, such as gamma or electron beam (e-beam) may be alternatively employed.

In one embodiment, the gelatin is contacted with a solution of approximately 25% glutaraldehyde for a selected period of time. One suitable form of glutaraldehyde is a grade 1G5882 glutaraldehyde available from Sigma Aldrich Company of Germany, although other glutaraldehyde solutions may also be used. The pH of the glutaraldehyde solution should be in the range of 7 to 7.8 and, more particularly, 7.35-7.44 and typically approximately 7.4+/−0.01. If necessary, the pH may be adjusted by adding a suitable amount of a base such as sodium hydroxide as needed.

Methods for forming the flexible portion of the shunt are shown for example in Yu et al. (U.S. patent application number 2008/0108933), the content of which is incorporated by reference herein in its entirety. In an exemplary protocol, the flexible portion may be made by dipping a core or substrate such as a wire of a suitable diameter in a solution of gelatin. The gelatin solution is typically prepared by dissolving a gelatin powder in de-ionized water or sterile water for injection and placing the dissolved gelatin in a water bath at a temperature of approximately 55° C. with thorough mixing to ensure complete dissolution of the gelatin. In one embodiment, the ratio of solid gelatin to water is approximately 10% to 50% gelatin by weight to 50% to 90% by weight of water. In an embodiment, the gelatin solution includes approximately 40% by weight, gelatin dissolved in water. The resulting gelatin solution should be devoid of air bubbles and has a viscosity that is between approximately 200-500 cp and more particularly between approximately 260 and 410 cp (centipoise).

Once the gelatin solution has been prepared, in accordance with the method described above, supporting structures such as wires having a selected diameter are dipped into the solution to form the flexible portion. Stainless steel wires coated with a biocompatible, lubricious material such as polytetrafluoroethylene (Teflon) are preferred.

Typically, the wires are gently lowered into a container of the gelatin solution and then slowly withdrawn. The rate of movement is selected to control the thickness of the coat. In addition, it is preferred that the tube be removed at a constant rate in order to provide the desired coating. To ensure that the gelatin is spread evenly over the surface of the wire, in one embodiment, the wires may be rotated in a stream of cool air which helps to set the gelatin solution and affix film onto the wire. Dipping and withdrawing the wire supports may be repeated several times to further ensure even coating of the gelatin. Once the wires have been sufficiently coated with gelatin, the resulting gelatin films on the wire may be dried at room temperature for at least 1 hour, and more preferably, approximately 10 to 24 hours. Apparatus for forming gelatin tubes are described in Yu et al. (U.S. patent application number 2008/0108933).

Once dried, the formed flexible portions may be treated with a cross-linking agent. In one embodiment, the formed flexible portion may be cross-linked by dipping the wire (with film thereon) into the 25% glutaraldehyde solution, at pH of approximately 7.0-7.8 and more preferably approximately 7.35-7.44 at room temperature for at least 4 hours and preferably between approximately 10 to 36 hours, depending on the degree of cross-linking desired. In one embodiment, the formed flexible portion is contacted with a cross-linking agent such as glutaraldehyde for at least approximately 16 hours. Cross-linking can also be accelerated when it is performed a high temperatures. It is believed that the degree of cross-linking is proportional to the bioabsorption time of the shunt once implanted. In general, the more cross-linking, the longer the survival of the shunt in the body.

The residual glutaraldehyde or other cross-linking agent is removed from the formed flexible portion by soaking the tubes in a volume of sterile water for injection. The water may optionally be replaced at regular intervals, circulated or re-circulated to accelerate diffusion of the unbound glutaraldehyde from the tube. The tubes are washed for a period of a few hours to a period of a few months with the ideal time being 3-14 days. The now cross-linked gelatin tubes may then be dried (cured) at ambient temperature for a selected period of time. It has been observed that a drying period of approximately 48-96 hours and more typically 3 days (i.e., 72 hours) may be preferred for the formation of the cross-linked gelatin tubes.

Where a cross-linking agent is used, it may be desirable to include a quenching agent in the method of making the flexible portion. Quenching agents remove unbound molecules of the cross-linking agent from the formed flexible portion. In certain cases, removing the cross-linking agent may reduce the potential toxicity to a patient if too much of the cross-linking agent is released from the flexible portion. In certain embodiments, the formed flexible portion is contacted with the quenching agent after the cross-linking treatment and, may be included with the washing/rinsing solution. Examples of quenching agents include glycine or sodium borohydride.

After the requisite drying period, the formed and cross-linked flexible portion is removed from the underlying supports or wires. In one embodiment, wire tubes may be cut at two ends and the formed gelatin flexible portion slowly removed from the wire support. In another embodiment, wires with gelatin film thereon, may be pushed off using a plunger or tube to remove the formed gelatin flexible portion.

Multi-Port Shunts

Other aspects of the invention generally provide multi-port shunts. Such shunts reduce probability of the shunt clogging after implantation because fluid can enter or exit the shunt even if one or more ports of the shunt become clogged with particulate. In certain embodiments, the shunt includes a hollow body defining a flow path and more than two ports, in which the body is configured such that a proximal portion receives fluid from the anterior chamber of an eye and a distal portion directs the fluid to drainage structures associated with the intrascleral space.

The shunt may have many different configurations. FIG. 8A shows an embodiment of a shunt 32 in which the proximal portion of the shunt (i.e., the portion disposed within the anterior chamber of the eye) includes more than one port (designated as numbers 33 a to 33 e) and the distal portion of the shunt (i.e., the portion that is located in the intrascleral space) includes a single port 34. FIG. 8B shows another embodiment of a shunt 32 in which the proximal portion includes a single port 33 and the distal portion includes more than one port (designated as numbers 34 a to 34 e). FIG. 8C shows another embodiment of a shunt 32 in which the proximal portions include more than one port (designated as numbers 33 a to 33 e) and the distal portions include more than one port (designated as numbers 34 a to 34 e). While FIGS. 8A-8C show shunts having five ports at the proximal portion, distal portion, or both, those shunts are only exemplary embodiments. The ports may be located along any portion of the shunt, and shunts disclosed herein include all shunts having more than two ports. For example, shunts disclosed herein may include at least three ports, at least four ports, at least five ports, at least 10 ports, at least 15 ports, or at least 20 ports.

The ports may be positioned in various different orientations and along various different portions of the shunt. In certain embodiments, at least one of the ports is oriented at an angle to the length of the body. In certain embodiments, at least one of the ports is oriented 90° to the length of the body. See for example FIG. 8A, which depicts ports 33 a, 33 b, 33 d, and 33 e as being oriented at a 90° angle to port 33 c.

The ports may have the same or different inner diameters. In certain embodiments, at least one of the ports has an inner diameter that is different from the inner diameters of the other ports. FIGS. 9A and 9B show an embodiment of a shunt 32 having multiple ports (33 a and 33 b) at a proximal end and a single port 34 at a distal end. FIG. 9A shows that port 33 b has an inner diameter that is different from the inner diameters of ports 33 a and 34. In this figure, the inner diameter of port 33 b is less than the inner diameter of ports 33 a and 34. An exemplary inner diameter of port 33 b is from about 20 μm to about 40 μm, particularly about 30 μm. In other embodiments, the inner diameter of port 33 b is greater than the inner diameter of ports 33 a and 34. See for example FIG. 9B.

The disclosure encompasses shunts of different shapes and different dimensions, and the shunts disclosed herein may be any shape or any dimension that may be accommodated by the eye. In certain embodiments, the intraocular shunt is of a cylindrical shape and has an outside cylindrical wall and a hollow interior. The shunt may have an inside diameter from approximately 10 μm to approximately 250 μm, an outside diameter from approximately 100 μm to approximately 450 μm, and a length from approximately 2 mm to approximately 10 mm. Shunts disclosed herein may be made from any biocompatible material. An exemplary material is gelatin. Methods of making shunts composed of gelatin are described above.

Shunts with Overflow Ports

Other aspects of the disclosure generally provide shunts with overflow ports. Those shunts are configured such that the overflow port remains partially or completely closed until there is a pressure build-up within the shunt sufficient to force open the overflow port. Such pressure build-up typically results from particulate partially or fully clogging an entry or an exit port of the shunt. Such shunts reduce probability of the shunt clogging after implantation because fluid can enter or exit the shunt by the overflow port even if one port of the shunt becomes clogged with particulate.

In certain embodiments, the shunt includes a hollow body defining an inlet configured to receive fluid from an anterior chamber of an eye and an outlet configured to direct the fluid to the intrascleral space, the body further including at least one slit. The slit may be located at any place along the body of the shunt. FIG. 10A shows a shunt 35 having an inlet 36, an outlet 37, and a slit 38 located in proximity to the inlet 36. FIG. 10B shows a shunt 35 having an inlet 36, an outlet 37, and a slit 39 located in proximity to the outlet 37. FIG. 10C shows a shunt 35 having an inlet 36, an outlet 37, a slit 38 located in proximity to the inlet 36, and a slit 39 located in proximity to the outlet 37.

While FIGS. 10A-10C show shunts have only a single overflow port at the proximal portion, the distal portion, or both the proximal and distal portions, those shunts are only exemplary embodiments. The overflow port(s) may be located along any portion of the shunt, and shunts disclosed herein include shunts having more than one overflow port. In certain embodiments, shunts disclosed herein include more than one overflow port at the proximal portion, the distal portion, or both. For example, FIG. 11 shows a shunt 40 having an inlet 41, an outlet 42, and slits 43 a and 43 b located in proximity to the inlet 41. Shunts disclosed herein may include at least two overflow ports, at least three overflow ports, at least four overflow ports, at least five overflow ports, at least 10 overflow ports, at least 15 overflow ports, or at least 20 overflow ports. In certain embodiments, shunts disclosed herein include two slits that overlap and are oriented at 90.degree. to each other, thereby forming a cross.

In certain embodiments, the slit may be at the proximal or the distal end of the shunt, producing a split in the proximal or the distal end of the implant. FIG. 12 shows an embodiment of a shunt 44 having an inlet 45, outlet 46, and a slit 47 that is located at the proximal end of the shunt, producing a split in the inlet 45 of the shunt.

In certain embodiments, the slit has a width that is substantially the same or less than an inner diameter of the inlet. In other embodiments, the slit has a width that is substantially the same or less than an inner diameter of the outlet. In certain embodiments, the slit has a length that ranges from about 0.05 mm to about 2 mm, and a width that ranges from about 10 μm to about 200 μm. Generally, the slit does not direct the fluid unless the outlet is obstructed. However, the shunt may be configured such that the slit does direct at least some of the fluid even if the inlet or outlet is not obstructed.

The disclosure encompasses shunts of different shapes and different dimensions, and the shunts disclosed herein may be any shape or any dimension that may be accommodated by the eye. In certain embodiments, the intraocular shunt is of a cylindrical shape and has an outside cylindrical wall and a hollow interior. The shunt may have an inside diameter from approximately 10 μm to approximately 250 μm, an outside diameter from approximately 100 μm to approximately 450 μm, and a length from approximately 2 mm to approximately 10 mm. Shunts disclosed herein may be made from any biocompatible material. An exemplary material is gelatin. Methods of making shunts composed of gelatin are described above.

Shunts Having a Variable Inner Diameter

In other aspects, the disclosure generally provides a shunt having a variable inner diameter. In particular embodiments, the diameter increases from inlet to outlet of the shunt. By having a variable inner diameter that increases from inlet to outlet, a pressure gradient is produced and particulate that may otherwise clog the inlet of the shunt is forced through the inlet due to the pressure gradient. Further, the particulate will flow out of the shunt because the diameter only increases after the inlet.

FIG. 13 shows an embodiment of a shunt 48 having an inlet 49 configured to receive fluid from an anterior chamber of an eye and an outlet 50 configured to direct the fluid to a location of lower pressure with respect to the anterior chamber, in which the body further includes a variable inner diameter that increases along the length of the body from the inlet 49 to the outlet 50. In certain embodiments, the inner diameter continuously increases along the length of the body, for example as shown in FIG. 13. In other embodiments, the inner diameter remains constant along portions of the length of the body.

In exemplary embodiments, the inner diameter may range in size from about 10 μm to about 200 μm, and the inner diameter at the outlet may range in size from about 15 μm to about 300 μm. The disclosure encompasses shunts of different shapes and different dimensions, and the shunts disclosed herein may be any shape or any dimension that may be accommodated by the eye. In certain embodiments, the intraocular shunt is of a cylindrical shape and has an outside cylindrical wall and a hollow interior. The shunt may have an inside diameter from approximately 10 μm to approximately 250 μm, an outside diameter from approximately 100 μm to approximately 450 μm, and a length from approximately 2 mm to approximately 10 mm. Shunts disclosed herein may be made from any biocompatible material. An exemplary material is gelatin. Methods of making shunts composed of gelatin are described above.

Shunts Having Pronged Ends

In other aspects, the disclosure generally provides shunts for facilitating conduction of fluid flow away from an organ, the shunt including a body, in which at least one end of the shunt is shaped to have a plurality of prongs. Such shunts reduce probability of the shunt clogging after implantation because fluid can enter or exit the shunt by any space between the prongs even if one portion of the shunt becomes clogged with particulate.

FIGS. 14A-14D show embodiments of a shunt 52 in which at least one end of the shunt 52 includes a plurality of prongs 53 a-d. FIGS. 14A-14D show embodiments in which both a proximal end and a distal end of the shunt are shaped to have the plurality of prongs. However, numerous different configurations are envisioned. For example, in certain embodiments, only the proximal end of the shunt is shaped to have the plurality of prongs. In other embodiments, only the distal end of the shunt is shaped to have the plurality of prongs.

Prongs 53 a-d can have any shape (i.e., width, length, height). FIGS. 14A-14B show prongs 53 a-d as straight prongs. In this embodiment, the spacing between the prongs 53 a-d is the same. In another embodiment shown in FIGS. 14C-14D, prongs 53 a-d are tapered. In this embodiment, the spacing between the prongs increases toward a proximal and/or distal end of the shunt 52.

FIGS. 14A-14D show embodiments that include four prongs. However, shunts disclosed herein may accommodate any number of prongs, such as two prongs, three prongs, four prongs, five prongs, six prongs, seven prongs, eight prongs, nine prongs, ten prongs, etc. The number of prongs chosen will depend on the desired flow characteristics of the shunt.

The disclosure encompasses shunts of different shapes and different dimensions, and the shunts disclosed herein may be any shape or any dimension that may be accommodated by the eye. In certain embodiments, the intraocular shunt is of a cylindrical shape and has an outside cylindrical wall and a hollow interior. The shunt may have an inside diameter from approximately 10 μm to approximately 250 μm, an outside diameter from approximately 100 μm to approximately 450 μm, and a length from approximately 2 mm to approximately 10 mm. Shunts disclosed herein may be made from any biocompatible material. An exemplary material is gelatin. Methods of making shunts composed of gelatin are described above.

Shunts Having a Longitudinal Slit

In other aspects, the disclosure generally provides a shunt for draining fluid from an anterior chamber of an eye that includes a hollow body defining an inlet configured to receive fluid from an anterior chamber of the eye and an outlet configured to direct the fluid to a location of lower pressure with respect to the anterior chamber; the shunt being configured such that at least one end of the shunt includes a longitudinal slit. Such shunts reduce probability of the shunt clogging after implantation because the end(s) of the shunt can more easily pass particulate which would generally clog a shunt lacking the slits.

FIGS. 15A-15D show embodiments of a shunt 54 in which at least one end of the shunt 54 includes a longitudinal slit 55 that produces a top portion 56 a and a bottom portion 56 b in a proximal and/or distal end of the shunt 54. FIGS. 15A-15D show an embodiment in which both a proximal end and a distal end include a longitudinal slit 55 that produces a top portion 56 a and a bottom portion 56 b in both ends of the shunt 54. However, numerous different configurations are envisioned. For example, in certain embodiments, only the proximal end of the shunt includes longitudinal slit 55. In other embodiments, only the distal end of the shunt includes longitudinal slit 55.

Longitudinal slit 55 can have any shape (i.e., width, length, height). FIGS. 15A-15B show a longitudinal slit 55 that is straight such that the space between the top portion 56 a and the bottom portion 56 b remains the same along the length of the slit 55. In another embodiment shown in FIGS. 15C-15D, longitudinal slit 55 is tapered. In this embodiment, the space between the top portion 45 a and the bottom portion 56 b increases toward a proximal and/or distal end of the shunt 54.

The disclosure encompasses shunts of different shapes and different dimensions, and the shunts disclosed herein may be any shape or any dimension that may be accommodated by the eye. In certain embodiments, the intraocular shunt is of a cylindrical shape and has an outside cylindrical wall and a hollow interior. The shunt may have an inside diameter from approximately 10 μm to approximately 250 μm, an outside diameter from approximately 100 μm to approximately 450 μm, and a length from approximately 2 mm to approximately 10 mm. Shunts disclosed herein may be made from any biocompatible material. An exemplary material is gelatin. Methods of making shunts composed of gelatin are described above.

Pharmaceutical Agents

In certain embodiments, shunts disclosed herein may be coated or impregnated with at least one pharmaceutical and/or biological agent or a combination thereof. The pharmaceutical and/or biological agent may coat or impregnate an entire exterior of the shunt, an entire interior of the shunt, or both. Alternatively, the pharmaceutical or biological agent may coat and/or impregnate a portion of an exterior of the shunt, a portion of an interior of the shunt, or both.

Methods of coating and/or impregnating an intraocular shunt with a pharmaceutical and/or biological agent are known in the art. See for example, Darouiche (U.S. Pat. Nos. 7,790,183; 6,719,991; 6,558,686; 6,162,487; 5,902,283; 5,853,745; and 5,624,704) and Yu et al. (U.S. patent application serial number 2008/0108933). The content of each of these references is incorporated by reference herein its entirety.

In certain embodiments, the exterior portion of the shunt that resides in the anterior chamber after implantation (e.g., about 1 mm of the proximal end of the shunt) is coated and/or impregnated with the pharmaceutical or biological agent. In other embodiments, the exterior of the shunt that resides in the scleral tissue after implantation of the shunt is coated and/or impregnated with the pharmaceutical or biological agent. In other embodiments, the exterior portion of the shunt that resides in the intrascleral space after implantation is coated and/or impregnated with the pharmaceutical or biological agent. In embodiments in which the pharmaceutical or biological agent coats and/or impregnates the interior of the shunt, the agent may be flushed through the shunt and into the area of lower pressure (e.g., the intrascleral space).

Any pharmaceutical and/or biological agent or combination thereof may be used with shunts disclosed herein. The pharmaceutical and/or biological agent may be released over a short period of time (e.g., seconds) or may be released over longer periods of time (e.g., days, weeks, months, or even years). Exemplary agents include anti-mitotic pharmaceuticals such as Mitomycin-C or 5-Fluorouracil, anti-VEGF (such as Lucentis, Macugen, Avastin, VEGF or steroids).

Deployment Devices

Any deployment device or system known in the art may be used with methods disclosed herein. In certain embodiments, deployment into the eye of an intraocular shunt according to the disclosure can be achieved using a hollow shaft configured to hold the shunt, as described herein. The hollow shaft can be coupled to a deployment device or part of the deployment device itself. Deployment devices that are suitable for deploying shunts according to the disclosure include but are not limited to the deployment devices described in U.S. Pat. Nos. 6,007,511, 6,544,249, and U.S. Publication No. US2008/0108933, the contents of which are each incorporated herein by reference in their entireties. In other embodiments, the deployment devices are devices as described in co-pending and co-owned U.S. nonprovisional patent application Ser. No. 12/946,222 filed on Nov. 15, 2010, or deployment devices described in co-pending and co-owned U.S. nonprovisional patent application Ser. No. 12/946,645 filed on Nov. 15, 2010, the entire content of each of which is incorporated by reference herein.

In still other embodiments, the shunts according to the disclosure are deployed into the eye using the deployment device 100 depicted in FIG. 16. While FIG. 16 shows a handheld manually operated shunt deployment device, it will be appreciated that devices disclosed herein may be coupled with robotic systems and may be completely or partially automated. As shown in FIG. 16, deployment device 100 includes a generally cylindrical body or housing 101, however, the body shape of housing 101 could be other than cylindrical. Housing 101 may have an ergonomical shape, allowing for comfortable grasping by an operator. Housing 101 is shown with optional grooves 102 to allow for easier gripping by a surgeon.

Housing 101 is shown having a larger proximal portion that tapers to a distal portion. The distal portion includes a hollow sleeve 105. The hollow sleeve 105 is configured for insertion into an eye and to extend into an anterior chamber of an eye. The hollow sleeve is visible within an anterior chamber of an eye. The sleeve may include an edge at a distal end that provides resistance feedback to an operator upon insertion of the deployment device 100 within an eye of a person. Upon advancement of the device 100 across an anterior chamber of the eye, the hollow sleeve 105 will eventually contact the sclera, providing resistance feedback to an operator that no further advancement of the device 100 is necessary. A temporary guard 108 is configured to fit around sleeve 105 and extend beyond an end of sleeve 105. The guard is used during shipping of the device and protects an operator from a distal end of a hollow shaft 104 that extends beyond the end of the sleeve 105. The guard is removed prior to use of the device.

Housing 101 is open at its proximal end, such that a portion of a deployment mechanism 103 may extend from the proximal end of the housing 101. A distal end of housing 101 is also open such that at least a portion of a hollow shaft 104 may extend through and beyond the distal end of the housing 101. Housing 101 further includes a slot 106 through which an operator, such as a surgeon, using the device 100 may view an indicator 107 on the deployment mechanism 103.

Housing 101 may be made of any material that is suitable for use in medical devices. For example, housing 101 may be made of a lightweight aluminum or a biocompatible plastic material. Examples of such suitable plastic materials include polycarbonate and other polymeric resins such as DELRIN and ULTEM. In certain embodiments, housing 101 is made of a material that may be autoclaved, and thus allow for housing 101 to be re-usable. Alternatively, device 100, may be sold as a one-time-use device, and thus the material of the housing does not need to be a material that is autoclavable.

Housing 101 may be made of multiple components that connect together to form the housing. FIG. 17 shows an exploded view of deployment device 100. In this figure, housing 101, is shown having three components 101 a, 101 b, and 101 c. The components are designed to screw together to form housing 101. FIGS. 18A-18D also show deployment mechanism 103. The housing 101 is designed such that deployment mechanism 103 fits within assembled housing 101. Housing 101 is designed such that components of deployment mechanism 103 are movable within housing 101.

FIGS. 18A-18D show different enlarged views of the deployment mechanism 103. Deployment mechanism 103 may be made of any material that is suitable for use in medical devices. For example, deployment mechanism 103 may be made of a lightweight aluminum or a biocompatible plastic material. Examples of such suitable plastic materials include polycarbonate and other polymeric resins such as DELRIN and ULTEM. In certain embodiments, deployment mechanism 103 is made of a material that may be autoclaved, and thus allow for deployment mechanism 103 to be re-usable. Alternatively, device 100 may be sold as a one-time-use device, and thus the material of the deployment mechanism does not need to be a material that is autoclavable.

Deployment mechanism 103 includes a distal portion 109 and a proximal portion 110. The deployment mechanism 103 is configured such that distal portion 109 is movable within proximal portion 110. More particularly, distal portion 109 is capable of partially retracting to within proximal portion 110.

In this embodiment, the distal portion 109 is shown to taper to a connection with a hollow shaft 104. This embodiment is illustrated such that the connection between the hollow shaft 104 and the distal portion 109 of the deployment mechanism 103 occurs inside the housing 101. In other embodiments, the connection between hollow shaft 104 and the distal portion 109 of the deployment mechanism 103 may occur outside of the housing 101. Hollow shaft 104 may be removable from the distal portion 109 of the deployment mechanism 103.

Alternatively, the hollow shaft 104 may be permanently coupled to the distal portion 109 of the deployment mechanism 103.

Generally, hollow shaft 104 is configured to hold an intraocular shunt, such as the intraocular shunts according to the disclosure. The shaft 104 may be any length. A usable length of the shaft may be anywhere from about 5 mm to about 40 mm, and is 15 mm in certain embodiments. In certain embodiments, the shaft is straight. In other embodiments, shaft is of a shape other than straight, for example a shaft having a bend along its length.

A proximal portion of the deployment mechanism includes optional grooves 116 to allow for easier gripping by an operator for easier rotation of the deployment mechanism, which will be discussed in more detail below. The proximal portion 110 of the deployment mechanism also includes at least one indicator that provides feedback to an operator as to the state of the deployment mechanism. The indicator may be any type of indicator known in the art, for example a visual indicator, an audio indicator, or a tactile indicator. FIGS. 18A-18D show a deployment mechanism having two indicators, a ready indicator 111 and a deployed indicator 119. Ready indicator 111 provides feedback to an operator that the deployment mechanism is in a configuration for deployment of an intraocular shunt from the deployment device 100. The ready indicator 111 is shown in this embodiment as a green oval having a triangle within the oval. Deployed indicator 119 provides feedback to the operator that the deployment mechanism has been fully engaged and has deployed the shunt from the deployment device 100. The deployed indicator 119 is shown in this embodiment as a yellow oval having a black square within the oval. The indicators are located on the deployment mechanism such that when assembled, the indicators 111 and 119 may be seen through slot 106 in housing 101.

The proximal portion 110 includes a stationary portion 110 b and a rotating portion 110 a. The proximal portion 110 includes a channel 112 that runs part of the length of stationary portion 110 b and the entire length of rotating portion 110 a. The channel 112 is configured to interact with a protrusion 117 on an interior portion of housing component 101 a (FIGS. 19A and 19B). During assembly, the protrusion 117 on housing component 101 a is aligned with channel 112 on the stationary portion 110 b and rotating portion 110 a of the deployment mechanism 103. The proximal portion 110 of deployment mechanism 103 is slid within housing component 101 a until the protrusion 117 sits within stationary portion 110 b (FIG. 19C). Assembled, the protrusion 117 interacts with the stationary portion 110 b of the deployment mechanism 103 and prevents rotation of stationary portion 110 b. In this configuration, rotating portion 110 a is free to rotate within housing component 101 a.

Referring back to FIGS. 18A-18D, the rotating portion 110 a of proximal portion 110 of deployment mechanism 103 also includes channels 113 a, 113 b, and 113 c. Channel 113 a includes a first portion 113 a 1 that is straight and runs perpendicular to the length of the rotating portion 110 a, and a second portion 113 a 2 that runs diagonally along the length of rotating portion 110 a, downwardly toward a proximal end of the deployment mechanism 103. Channel 113 b includes a first portion 113 b 1 that runs diagonally along the length of the rotating portion 110 a, downwardly toward a distal end of the deployment mechanism 103, and a second portion that is straight and runs perpendicular to the length of the rotating portion 110 a. The point at which first portion 113 a 1 transitions to second portion 113 a 2 along channel 113 a, is the same as the point at which first portion 113 b 1 transitions to second portion 113 b 2 along channel 113 b. Channel 113 c is straight and runs perpendicular to the length of the rotating portion 110 a. Within each of channels 113 a, 113 b, and 113 c, sit members 114 a, 114 b, and 114 c respectively.

Members 114 a, 114 b, and 114 c are movable within channels 113 a, 113 b, and 113 c. Members 114 a, 114 b, and 114 c also act as stoppers that limit movement of rotating portion 110 a, which thereby limits axial movement of the shaft 104.

FIG. 20 shows a cross-sectional view of deployment mechanism 103. Member 114 a is connected to the distal portion 109 of the deployment mechanism 103. Movement of member 114 a results in retraction of the distal portion 109 of the deployment mechanism 103 to within the proximal portion 110 of the deployment mechanism 103. Member 114 b is connected to a pusher component 118. The pusher component 118 extends through the distal portion 109 of the deployment mechanism 103 and extends into a portion of hollow shaft 104. The pusher component is involved in deployment of a shunt from the hollow shaft 104. An exemplary pusher component is a plunger. Movement of member 114 b engages pusher 118 and results in pusher 118 advancing within hollow shaft 104.

Reference is now made to FIGS. 23A-23D, which accompany the following discussion regarding deployment of a shunt 115 from deployment device 100. FIG. 21A shows deployment device 100 in a pre-deployment configuration. In this configuration, shunt 115 is loaded within hollow shaft 104 (FIG. 21C). As shown in FIG. 21C, shunt 115 is only partially within shaft 104, such that a portion of the shunt is exposed. However, the shunt 115 does not extend beyond the end of the shaft 104. In other embodiments, the shunt 115 is completely disposed within hollow shaft 104. The shunt 115 is loaded into hollow shaft 104 such that the shunt abuts pusher component 118 within hollow shaft 104. A distal end of shaft 104 is beveled to assist in piercing tissue of the eye.

Additionally, in the pre-deployment configuration, a portion of the shaft 104 extends beyond the sleeve 105 (FIG. 21C). The deployment mechanism is configured such that member 114 a abuts a distal end of the first portion 113 a 1 of channel 113 a, and member 114 b abuts a proximal end of the first portion 113 b 1 of channel 113 b (FIG. 21B). In this configuration, the ready indicator 111 is visible through slot 106 of the housing 101, providing feedback to an operator that the deployment mechanism is in a configuration for deployment of an intraocular shunt from the deployment device 100 (FIG. 21A). In this configuration, the device 100 is ready for insertion into an eye (insertion configuration or pre-deployment configuration). Methods for inserting and implanting shunts are discussed in further detail below.

Once the device has been inserted into the eye and advanced to a location to where the shunt will be deployed, the shunt 115 may be deployed from the device 100. The deployment mechanism 103 is a two-stage system. The first stage is engagement of the pusher component 118 and the second stage is retraction of the distal portion 109 to within the proximal portion 110 of the deployment mechanism 103. Rotation of the rotating portion 110 a of the proximal portion 110 of the deployment mechanism 103 sequentially engages the pusher component and then the retraction component.

In the first stage of shunt deployment, the pusher component is engaged and the pusher partially deploys the shunt from the deployment device. During the first stage, rotating portion 110 a of the proximal portion 110 of the deployment mechanism 103 is rotated, resulting in movement of members 114 a and 114 b along first portions 113 a 1 and 113 b 1 in channels 113 a and 113 b. Since the first portion 113 a 1 of channel 113 a is straight and runs perpendicular to the length of the rotating portion 110 a, rotation of rotating portion 110 a does not cause axial movement of member 114 a. Without axial movement of member 114 a, there is no retraction of the distal portion 109 to within the proximal portion 110 of the deployment mechanism 103.

Since the first portion 113 b 1 of channel 113 b runs diagonally along the length of the rotating portion 110 a, upwardly toward a distal end of the deployment mechanism 103, rotation of rotating portion 110 a causes axial movement of member 114 b toward a distal end of the device. Axial movement of member 114 b toward a distal end of the device results in forward advancement of the pusher component 118 within the hollow shaft 104. Such movement of pusher component 118 results in partial deployment of the shunt 115 from the shaft 104.

FIGS. 22A to 22C show schematics of the deployment mechanism at the end of the first stage of deployment of the shunt from the deployment device. As is shown FIG. 22A, members 114 a and 114 b have finished traversing along first portions 113 a 1 and 113 b 1 of channels 113 a and 113 b. Additionally, pusher component 118 has advanced within hollow shaft 104 (FIG. 22B), and shunt 115 has been partially deployed from the hollow shaft 104 (FIG. 22C). As is shown in these figures, a portion of the shunt 115 extends beyond an end of the shaft 104.

In the second stage of shunt deployment, the retraction component is engaged and the distal portion of the deployment mechanism is retracted to within the proximal portion of the deployment mechanism, thereby completing deployment of the shunt from the deployment device. During the second stage, rotating portion 110 a of the proximal portion 110 of the deployment mechanism 103 is further rotated, resulting in movement of members 114 a and 114 b along second portions 113 a 2 and 113 b 2 in channels 113 a and 113 b. Since the second portion 113 b 2 of channel 113 b is straight and runs perpendicular to the length of the rotating portion 110 a, rotation of rotating portion 110 a does not cause axial movement of member 114 b. Without axial movement of member 114 b, there is no further advancement of pusher component 118. Since the second portion 113 a 2 of channel 113 a runs diagonally along the length of the rotating portion 110 a, downwardly toward a proximal end of the deployment mechanism 103, rotation of rotating portion 110 a causes axial movement of member 114 a toward a proximal end of the device. Axial movement of member 114 a toward a proximal end of the device results in retraction of the distal portion 109 to within the proximal portion 110 of the deployment mechanism 103. Retraction of the distal portion 109, results in retraction of the hollow shaft 104. Since the shunt 115 abuts the pusher component 118, the shunt remains stationary as the hollow shaft 104 retracts from around the shunt 115 (FIG. 22C). The shaft 104 retracts almost completely to within the sleeve 105. During both stages of the deployment process, the sleeve 105 remains stationary and in a fixed position.

FIGS. 23A-23D show schematics of the device 100 after deployment of the shunt 115 from the device 100. FIG. 23B shows a schematic of the deployment mechanism at the end of the second stage of deployment of the shunt from the deployment device. As is shown in FIG. 23B, members 114 a and 114 b have finished traversing along second portions 113 a 2 and 113 b 2 of channels 113 a and 113 b. Additionally, distal portion 109 has retracted to within proximal portion 110, thus resulting in retraction of the hollow shaft 104 to within the sleeve 105. FIG. 23D shows an enlarged view of the distal portion of the deployment device after deployment of the shunt. This figure shows that the hollow shaft 104 is not fully retracted to within the sleeve 105 of the deployment device 100. However, in certain embodiments, the shaft 104 may completely retract to within the sleeve 105.

INCORPORATION BY REFERENCE

References and citations to other documents, such as patents, patent applications, patent publications, journals, books, papers, web contents, have been made throughout this disclosure. All such documents are hereby incorporated herein by reference in their entirety for all purposes.

EQUIVALENTS

The present inventions may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The foregoing embodiments are therefore to be considered in all respects illustrative rather than limiting on the inventions described herein. Scope of the inventions is thus indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. 

What is claimed is:
 1. A method for implanting an intraocular shunt in an eye, the eye comprising a sclera and an anterior chamber, the method comprising the steps of: creating a passage completely through the sclera of the eye to form a scleral channel having an exit at an outer surface of the sclera; and positioning a shunt in the passage such that, in a final position, (i) an inlet end of the shunt is in the anterior chamber and (ii) an outlet end of the shunt is positioned within the scleral channel and spaced apart from the exit to form a scleral slit for providing resistance to outflow of aqueous humor.
 2. The method of claim 1, wherein the outlet end of the shunt is spaced apart about 200-500 μm from the scleral slit.
 3. The method of claim 1, wherein the outlet end of the shunt is spaced apart more than 500 μm from the scleral slit.
 4. The method of claim 1, wherein the creating comprises advancing a shaft of an inserter through a cornea of the eye.
 5. The method of claim 4, wherein the shunt is carried by the shaft.
 6. The method of claim 5, wherein the shunt is disposed at least partially within the shaft.
 7. The method of claim 4, wherein the creating comprises inserting the shaft between about 0.25 mm to about 3.0 mm above a corneal limbus of the eye.
 8. The method of claim 1, wherein the creating comprises advancing a shaft of an inserter through conjunctiva of the eye.
 9. The method of claim 1, wherein the creating comprises inserting a surgical tool through the sclera to form the passage completely through the sclera before inserting the shunt.
 10. A method for implanting an intraocular shunt in an eye, the method comprising: creating a passage completely through a sclera of the eye, the passage having an exit that forms a scleral slit at a scleral surface adjacent to a subconjunctival space of the eye; inserting an intraocular shunt into the eye, the shunt having an inlet end and an outlet end; positioning the inlet end of the shunt in an anterior chamber of the eye; and positioning the outlet end of the shunt in the sclera of the eye, such that the outlet end lies entirely within the passage, wherein the scleral slit is configured to open for permitting fluid flow from the anterior chamber to the subconjunctival space.
 11. The method of claim 10, wherein the outlet end of the shunt is spaced apart from the scleral slit.
 12. The method of claim 11, wherein the outlet end of the shunt is spaced apart about 200-500 μm from the scleral slit.
 13. The method of claim 11, wherein the outlet end of the shunt is spaced apart more than 500 μm from the scleral slit.
 14. The method of claim 10, wherein the creating comprises advancing a shaft of an inserter through conjunctiva of the eye.
 15. A method for regulating fluid pressure in an eye, the method comprising: advancing a surgical tool through sclera of the eye to form a scleral channel from an anterior chamber to an exit at a subconjunctival location; and positioning an intraocular shunt within the scleral channel to form a closeable scleral slit that opens upon communication of fluid pressure from the anterior chamber to the scleral slit.
 16. The method of claim 15, wherein an outlet end of the shunt is spaced apart from the scleral slit.
 17. The method of claim 16, wherein the outlet end of the shunt is spaced apart about 200-500 μm from the scleral slit.
 18. The method of claim 16, wherein the outlet end of the shunt is spaced apart more than 500 μm from the scleral slit. 